Cytokinins are a class of phytohormones that promote cell division and differentiation and are thought to affect plant immunity to multiple pathogens.However,a comprehensive analysis of cytokinin dehydrogenase/oxidase...Cytokinins are a class of phytohormones that promote cell division and differentiation and are thought to affect plant immunity to multiple pathogens.However,a comprehensive analysis of cytokinin dehydrogenase/oxidase(CKX)family genes in cabbage has not been reported.In this study,a total of 36 CKX genes were identified using a genome-wide search method.Phylogenetic analysis classified these genes into three groups.They were distributed unevenly across nine chromosomes in B.oleracea,and 15 of them did not contain any introns.The results of colinearity analysis showed that 36 CKX gene in Arabidopsis was present in several copies in the Brassica oleracea genome.An analysis of cisacting elements indicated that all genes possessed at least one stress or hormone responsive cis-acting element.A heatmap of CKX gene expression showed the patterns of expression of these genes in various tissues and organs.Three genes(Bol028363,Bol031036 and Bol018140)were relatively highly expressed in all of the investigated tissues under normal conditions,showing the expression profile of housekeeping genes.Generally,the expression patterns of CKX genes in Jingfeng 1 and Xiangan 336 were quite different under the same treatment.Notably,three genes(Bol020547,Bol028392 and Bol045724)were significantly down-regulated and up-regulated in the susceptible and resistant material,respectively,after inoculation,which may indicate their crucial roles in resistance to clubroot disease.The results provide insights for better understanding the roles of CKX genes in the B.oleracea–P.brassicae interaction.展开更多
Clubroot disease,a major plant root disease caused by Plasmodiophora brassicae,has become one of the most destructive diseases among cultivated cruciferous vegetables.However,clubroot-resistant Brassica oleracea mater...Clubroot disease,a major plant root disease caused by Plasmodiophora brassicae,has become one of the most destructive diseases among cultivated cruciferous vegetables.However,clubroot-resistant Brassica oleracea materials are rare.A few clubroot-resistant cabbage varieties are available on the market,but all are Ogura cytoplasmic male sterile(CMS)types.Therefore,in this study,to reutilize the clubroot-resistant Ogura CMS germplasm of cabbage,a new fertility-restored Ogura CMS material,16Q2-11,was used as a bridge to transfer the clubroot resistance(CR)gene from the Ogura CMS cytoplasm to the normal cytoplasm by a two-step method(a fertility restoration and cytoplasm replacement method).In the first cross for fertility restoration of Ogura CMS clubroot-resistant cabbage(FRCRC),16Q2-11 was used as a restorer to cross with Ogura CMS materials containing the CR gene CRb2.Eleven Rfo-positive progenies were generated,of which four contained CRb2:F8-514,F8-620,F8-732 and F8-839.After inoculation with race 4 of P.brassicae,these four CRb2-positive individuals showed resistance.Furthermore,F8-514 and F8-839 were then used as male parents in the second cross of FRCRC to cross with cabbage inbred lines,resulting in the successful introgression of the CRb2 gene into the inbred lines.All offspring produced from this step of cross,which had a normal cytoplasm,showed a high resistance to race 4 of P.brassicae and could be utilized for the breeding of clubrootresistant cabbage varieties in the future.This is the first time that the Ogura CMS restorer has been used to restore the fertility of Ogura CMS clubroot-resistant cabbages,which could improve germplasm diversity in cabbage and provide a reference method for using CMS germplasm in Brassica crops.展开更多
At the time of writing,the coronavirus disease(COVID-19)has affected 212 countries and territories across the globe.According to the world health organization(WHO),a total number of 4,735,622 confirmed cases,including...At the time of writing,the coronavirus disease(COVID-19)has affected 212 countries and territories across the globe.According to the world health organization(WHO),a total number of 4,735,622 confirmed cases,including 316,289 deaths was reported[1].In the fight against COVID-19,nurses,doctors,and other healthcare workers are in the front line of the battle bearing the higher risk of infection[2].The International Council of Nurses(ICN)gathered further information to suggest that more than 90,000 healthcare workers have been infected worldwide[3].Personal protective equipment(PPE)shortage is one of the key factors increasing the infection risk for the medical staffs.Therefore,finding alternative ways to lower the infection risk has become an urgent problem to be solved.展开更多
To better understand the genetic diversity and population structure of broccoli cultivars planted in China,a total of 161 representative broccoli cultivars in the past 25 years were collected and analysed based on sin...To better understand the genetic diversity and population structure of broccoli cultivars planted in China,a total of 161 representative broccoli cultivars in the past 25 years were collected and analysed based on single nucleotide polymorphism(SNP)markers.Ten pairs of primers with good polymorphism and high resolution were screened from 315 pairs of SNP primers by 3 broccoli accessions(inbred lines)with different phenotypes and maturity.The 10 pairs of SNP primers were selected,producing 78 alleles.The diversity analysis indicated that the polymorphism information content(PIC)of SNP primer ranged from 0.64 to 0.90.The observed number of alleles(Na)was 2.00,the effective number of alleles(Ne)was 1.11–2.00,the Nei’s gene diversity(H)was 0.10–0.50,and Shannon information index(I)was 0.20–0.70 using PopGene32 software.The clustering results showed that the 161 broccoli cultivars could be divided into 4 major subgroups(A,B,C and D),foreign cultivars were all assigned to subgroup A,and domestic cultivars were assigned to 3 subgroups of B,C,and D.This study indicated that some domestic cultivars and foreign cultivars were similar in genetic background,but most domestic cultivars were still different from the Japanese cultivars.When K=2,the population structure result presented that 161 broccoli cultivars could be divided into 1 simple group(2 groups)and 1 mixed group.When Q≥0.6,143(88.82%)broccoli cultivars belonged to the simple groups.In simple groups 68(42.24%)broccoli cultivars of group 1 were derived from Japan,the United States,Switzerland,the Netherlands,China-Taiwan,and China-Mainland;75(46.58%)broccoli cultivars belonged to group 2;when Q<0.6,18(11.18%)broccoli cultivars belonged to the mixed groups.This study is helpful to understand the diversity and resolution of broccoli cultivars from worldwide,which is beneficial to plant breeding and materials innovation.And meanwhile,this result is also used for construction of broccoli fingerprint serving for cultivar identification.展开更多
Brassica species include many economically important crops that provide nutrition and health-promoting substances to humans worldwide.However,as with all crops,their production is constantly threatened by emerging vir...Brassica species include many economically important crops that provide nutrition and health-promoting substances to humans worldwide.However,as with all crops,their production is constantly threatened by emerging viral,bacterial,and fungal diseases,whose incidence has increased in recent years.Traditional methods of control are often costly,present limited effectiveness,and cause environmental damage;instead,the ideal approach is to mine and utilize the resistance genes of the Brassica crop hosts themselves.Fortunately,the development of genomics,molecular genetics,and biological techniques enables us to rapidly discover and apply resistance(R)genes.Herein,the R genes identified in Brassica crops are summarized,including their mapping and cloning,possible molecular mechanisms,and application in resistance breeding.Future perspectives concerning how to accurately discover additional R gene resources and efficiently utilize these genes in the genomic era are also discussed.展开更多
Cabbage has significant heterosis and most commercial cultivars are hybrids.To explore genetic basis of cabbage heterosis and promote cabbage heterosis utilization,we constructed two populations by crossing 100 DH lin...Cabbage has significant heterosis and most commercial cultivars are hybrids.To explore genetic basis of cabbage heterosis and promote cabbage heterosis utilization,we constructed two populations by crossing 100 DH lines derived from a cabbage hybrid 01–20×96–100 with two female parents.Hybrids exhibited different extents of heterosis,the mean value of economic yield was 2.6 times bigger than parents.We identified 66 and 73 QTLs associated with mid-parent heterosis and transgressive heterosis of twelve yield-related traits,respectively.Some QTLs could be detected under the two-year experiment existed in two populations with different testers,showing relatively high phenotypic contribution rate(15.8%–20.0%).Heterosis QTLs exhibited clustered distribution in several cabbage chromosome regions.Two dominant genetic regions,mk300–316 and mk258–268,originated from the elite parent 01–20,exhibited significant genetic effects for yield-related heterosis,which were first identified.Three elite DH lines(D22,D46,D83)harboring these two dominant regions were selected as having strong heterosis in cabbage production.Candidate gene analysis revealed that some genes participating in biosynthetic processes of carbohydrates and some responses to auxin might affect cabbage yield heterosis.QTL identification and genetic dissection of yield-related traits provide new insights into the genetic effects of cabbage heterosis.展开更多
Brassica oleracea comprises several important vegetable and ornamental crops,including curly kale,ornamental kale,cabbage,broccoli,and others.The accumulation of anthocyanins,important secondary metabolites valuable t...Brassica oleracea comprises several important vegetable and ornamental crops,including curly kale,ornamental kale,cabbage,broccoli,and others.The accumulation of anthocyanins,important secondary metabolites valuable to human health,in these plants varies widely and is responsible for their pink to dark purple colors.Some curly kale varieties lack anthocyanins,making these plants completely green.The genetic basis of this trait is still unknown.We crossed the curly kale inbred line BK2019(without anthocyanins)with the cabbage inbred line YL1(with anthocyanins)and the Chinese kale inbred line TO1000(with anthocyanins)to generate segregating populations.The no-anthocyanin trait was genetically controlled by a recessive gene,bona1.We generated a linkage map and mapped bona1 to a 256-kb interval on C09.We identified one candidate gene,Bo9g058630,in the target genomic region;this gene is homologous to AT5G42800,which encodes a dihydroflavonol-4-reductase-like(DFR-like)protein in Arabidopsis.In BK2019,a 1-bp insertion was observed in the second exon of Bo9g058630 and directly produced a stop codon.To verify the candidate gene function,CRISPR/Cas9 gene editing technology was applied to knock out Bo9g058630.We generated three bona1 mutants,two of which were completely green with no anthocyanins,confirming that Bo9g058630 corresponds to BoNA1.Different insertion/deletion mutations in BoNA1 exons were found in all six of the other no-anthocyanin kale varieties examined,supporting that independent disruption of BoNA1 resulted in no-anthocyanin varieties of B.oleracea.This study improves the understanding of the regulation mechanism of anthocyanin accumulation in B.oleracea subspecies.展开更多
1 Introduction Digital Twin(DT)is built and maintained in the digital rather physical realm[1,2].Dynamic DT mirrors the exact state of the physical system by means of multidimensional models describing the behavior of...1 Introduction Digital Twin(DT)is built and maintained in the digital rather physical realm[1,2].Dynamic DT mirrors the exact state of the physical system by means of multidimensional models describing the behavior of physical entity,and sensors providing the real-time coupling to models[3].Te outbreak of COVID-19 pandemic results in speeding up the virtualization and digitization of the physical entity with the support from DT.Nevertheless,quarantine and division led by COVID-19 pandemic make human beings’eyes for the physical interaction become more eager.Te physical world and the digital world are becoming interwoven,which indicates a new opportunity towards phygital twin.As is so often the question:how can I get closer to my distant companion?How can I extend my service or emotional concern to facilitate interaction in spite of space obstruction?Tese questions deserve thinking as a lesson learned from outbreak of COVID-19 pandemic.展开更多
Brassica oleracea is an important biennial herbaceous species in the Cruciferae family.With an estimated 3.77 million hectares planted worldwide,these cole crops,for instance,cabbage,broccoli,and cauliflower,constitut...Brassica oleracea is an important biennial herbaceous species in the Cruciferae family.With an estimated 3.77 million hectares planted worldwide,these cole crops,for instance,cabbage,broccoli,and cauliflower,constitute significant agricultural resources(Li et al.,2024).In recent years,the clustered regularly interspaced short palindromic repeats(CRISPR)/CRISPR-associated protein 9(Cas9)technology has been extensively applied in major crops,including rice,wheat,and potato.This technology can be utilized to regulate or disrupt gene expression to develop high-quality,disease-resistant.展开更多
Global food production is a major challenge currently facing humanity,and the primary way to secure global food security is to increase crop yields and enhance nutritional value.Heterosis utilization by crossing of tw...Global food production is a major challenge currently facing humanity,and the primary way to secure global food security is to increase crop yields and enhance nutritional value.Heterosis utilization by crossing of two different homozygous inbred lines has long been applied to increase crop yield.Doubled haploid(DH)technology greatly shortens the breeding process of homozygous lines by up to 3-5 years.In recent years,new haploid induction(HI)techniques based on genes such as DOMAIN OF UNKNOWN FUNCTION 679 membrane protein(DMP)and CENTROMERIC HISTONE3(CENH3)were exciting progresses in generating DHs in a more efficient and simple way(Jiang et al.,2022;Qu et al.,2024).展开更多
基金supported by the Youth Science Fund Project(Grant No. 31801876)。
文摘Cytokinins are a class of phytohormones that promote cell division and differentiation and are thought to affect plant immunity to multiple pathogens.However,a comprehensive analysis of cytokinin dehydrogenase/oxidase(CKX)family genes in cabbage has not been reported.In this study,a total of 36 CKX genes were identified using a genome-wide search method.Phylogenetic analysis classified these genes into three groups.They were distributed unevenly across nine chromosomes in B.oleracea,and 15 of them did not contain any introns.The results of colinearity analysis showed that 36 CKX gene in Arabidopsis was present in several copies in the Brassica oleracea genome.An analysis of cisacting elements indicated that all genes possessed at least one stress or hormone responsive cis-acting element.A heatmap of CKX gene expression showed the patterns of expression of these genes in various tissues and organs.Three genes(Bol028363,Bol031036 and Bol018140)were relatively highly expressed in all of the investigated tissues under normal conditions,showing the expression profile of housekeeping genes.Generally,the expression patterns of CKX genes in Jingfeng 1 and Xiangan 336 were quite different under the same treatment.Notably,three genes(Bol020547,Bol028392 and Bol045724)were significantly down-regulated and up-regulated in the susceptible and resistant material,respectively,after inoculation,which may indicate their crucial roles in resistance to clubroot disease.The results provide insights for better understanding the roles of CKX genes in the B.oleracea–P.brassicae interaction.
基金supported by the Major State Research Development Program(2016YFD0101702)the Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences(CAASASTIP-IVFCAAS)the earmarked fund for the Modern Agro-Industry Technology Research System,China(nycytx-35-gw01).
文摘Clubroot disease,a major plant root disease caused by Plasmodiophora brassicae,has become one of the most destructive diseases among cultivated cruciferous vegetables.However,clubroot-resistant Brassica oleracea materials are rare.A few clubroot-resistant cabbage varieties are available on the market,but all are Ogura cytoplasmic male sterile(CMS)types.Therefore,in this study,to reutilize the clubroot-resistant Ogura CMS germplasm of cabbage,a new fertility-restored Ogura CMS material,16Q2-11,was used as a bridge to transfer the clubroot resistance(CR)gene from the Ogura CMS cytoplasm to the normal cytoplasm by a two-step method(a fertility restoration and cytoplasm replacement method).In the first cross for fertility restoration of Ogura CMS clubroot-resistant cabbage(FRCRC),16Q2-11 was used as a restorer to cross with Ogura CMS materials containing the CR gene CRb2.Eleven Rfo-positive progenies were generated,of which four contained CRb2:F8-514,F8-620,F8-732 and F8-839.After inoculation with race 4 of P.brassicae,these four CRb2-positive individuals showed resistance.Furthermore,F8-514 and F8-839 were then used as male parents in the second cross of FRCRC to cross with cabbage inbred lines,resulting in the successful introgression of the CRb2 gene into the inbred lines.All offspring produced from this step of cross,which had a normal cytoplasm,showed a high resistance to race 4 of P.brassicae and could be utilized for the breeding of clubrootresistant cabbage varieties in the future.This is the first time that the Ogura CMS restorer has been used to restore the fertility of Ogura CMS clubroot-resistant cabbages,which could improve germplasm diversity in cabbage and provide a reference method for using CMS germplasm in Brassica crops.
基金supported by the National Natural Science Foundation of China (51975513)the Natural Science Foundation of Zhejiang Province (LR20E050003)+4 种基金the Zhejiang University Special Scientific Research Fund for COVID-19 Prevention and Control (2020XGZX017)China’s Thousand Talents Plan Young Professionals Program, Major Research Plan (51890884)State Key Laboratory of Fluid Power and Mechatronic Systems (SKLo FP_ZZ_2002)Science Fund for Creative Research Groups (51821093)Robotics Institute of Zhejiang University (K18-508116-008-03)
文摘At the time of writing,the coronavirus disease(COVID-19)has affected 212 countries and territories across the globe.According to the world health organization(WHO),a total number of 4,735,622 confirmed cases,including 316,289 deaths was reported[1].In the fight against COVID-19,nurses,doctors,and other healthcare workers are in the front line of the battle bearing the higher risk of infection[2].The International Council of Nurses(ICN)gathered further information to suggest that more than 90,000 healthcare workers have been infected worldwide[3].Personal protective equipment(PPE)shortage is one of the key factors increasing the infection risk for the medical staffs.Therefore,finding alternative ways to lower the infection risk has become an urgent problem to be solved.
基金funded by the National Key Research and Development Plan(Grant No.2017YFD0101805)the National Science and Technology Foundation(Grant No.31501761)+2 种基金the National Modern Agricultural Industry Technology System Construction Special Fund Project(Grant No.CARS-23-A8)the Chinese Academy of Agricultural Sciences Science and Technology Innovation Project(Grant No.CAAS-ASTIP-IVF-CAAS)the State Key Laboratory of Vegetable Germplasm Innovation.
文摘To better understand the genetic diversity and population structure of broccoli cultivars planted in China,a total of 161 representative broccoli cultivars in the past 25 years were collected and analysed based on single nucleotide polymorphism(SNP)markers.Ten pairs of primers with good polymorphism and high resolution were screened from 315 pairs of SNP primers by 3 broccoli accessions(inbred lines)with different phenotypes and maturity.The 10 pairs of SNP primers were selected,producing 78 alleles.The diversity analysis indicated that the polymorphism information content(PIC)of SNP primer ranged from 0.64 to 0.90.The observed number of alleles(Na)was 2.00,the effective number of alleles(Ne)was 1.11–2.00,the Nei’s gene diversity(H)was 0.10–0.50,and Shannon information index(I)was 0.20–0.70 using PopGene32 software.The clustering results showed that the 161 broccoli cultivars could be divided into 4 major subgroups(A,B,C and D),foreign cultivars were all assigned to subgroup A,and domestic cultivars were assigned to 3 subgroups of B,C,and D.This study indicated that some domestic cultivars and foreign cultivars were similar in genetic background,but most domestic cultivars were still different from the Japanese cultivars.When K=2,the population structure result presented that 161 broccoli cultivars could be divided into 1 simple group(2 groups)and 1 mixed group.When Q≥0.6,143(88.82%)broccoli cultivars belonged to the simple groups.In simple groups 68(42.24%)broccoli cultivars of group 1 were derived from Japan,the United States,Switzerland,the Netherlands,China-Taiwan,and China-Mainland;75(46.58%)broccoli cultivars belonged to group 2;when Q<0.6,18(11.18%)broccoli cultivars belonged to the mixed groups.This study is helpful to understand the diversity and resolution of broccoli cultivars from worldwide,which is beneficial to plant breeding and materials innovation.And meanwhile,this result is also used for construction of broccoli fingerprint serving for cultivar identification.
基金supported by grants from the National Natural Science Foundation of China(31701927)Central Public-Interest Scientific Institution Basal Research Fund(Y2020PT01,Y2018YJ04)+1 种基金earmarked fund for the Modern Agro-Industry Technology Research System,China(CARS-23)the Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences(CAAS-ASTIP-IVFCAAS).
文摘Brassica species include many economically important crops that provide nutrition and health-promoting substances to humans worldwide.However,as with all crops,their production is constantly threatened by emerging viral,bacterial,and fungal diseases,whose incidence has increased in recent years.Traditional methods of control are often costly,present limited effectiveness,and cause environmental damage;instead,the ideal approach is to mine and utilize the resistance genes of the Brassica crop hosts themselves.Fortunately,the development of genomics,molecular genetics,and biological techniques enables us to rapidly discover and apply resistance(R)genes.Herein,the R genes identified in Brassica crops are summarized,including their mapping and cloning,possible molecular mechanisms,and application in resistance breeding.Future perspectives concerning how to accurately discover additional R gene resources and efficiently utilize these genes in the genomic era are also discussed.
基金financially supported by the Major State Research Development Program(Grant No.2016YFD0101702)the National Natural Science Foundation of China(Grant No.31872948)the Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences(CAAS-ASTIPIVFCAAS)。
文摘Cabbage has significant heterosis and most commercial cultivars are hybrids.To explore genetic basis of cabbage heterosis and promote cabbage heterosis utilization,we constructed two populations by crossing 100 DH lines derived from a cabbage hybrid 01–20×96–100 with two female parents.Hybrids exhibited different extents of heterosis,the mean value of economic yield was 2.6 times bigger than parents.We identified 66 and 73 QTLs associated with mid-parent heterosis and transgressive heterosis of twelve yield-related traits,respectively.Some QTLs could be detected under the two-year experiment existed in two populations with different testers,showing relatively high phenotypic contribution rate(15.8%–20.0%).Heterosis QTLs exhibited clustered distribution in several cabbage chromosome regions.Two dominant genetic regions,mk300–316 and mk258–268,originated from the elite parent 01–20,exhibited significant genetic effects for yield-related heterosis,which were first identified.Three elite DH lines(D22,D46,D83)harboring these two dominant regions were selected as having strong heterosis in cabbage production.Candidate gene analysis revealed that some genes participating in biosynthetic processes of carbohydrates and some responses to auxin might affect cabbage yield heterosis.QTL identification and genetic dissection of yield-related traits provide new insights into the genetic effects of cabbage heterosis.
基金This work was funded by the Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences(CAASASTIPIVFCAAS)the China Agriculture Research System of MOF and MARA(CARS-23).
文摘Brassica oleracea comprises several important vegetable and ornamental crops,including curly kale,ornamental kale,cabbage,broccoli,and others.The accumulation of anthocyanins,important secondary metabolites valuable to human health,in these plants varies widely and is responsible for their pink to dark purple colors.Some curly kale varieties lack anthocyanins,making these plants completely green.The genetic basis of this trait is still unknown.We crossed the curly kale inbred line BK2019(without anthocyanins)with the cabbage inbred line YL1(with anthocyanins)and the Chinese kale inbred line TO1000(with anthocyanins)to generate segregating populations.The no-anthocyanin trait was genetically controlled by a recessive gene,bona1.We generated a linkage map and mapped bona1 to a 256-kb interval on C09.We identified one candidate gene,Bo9g058630,in the target genomic region;this gene is homologous to AT5G42800,which encodes a dihydroflavonol-4-reductase-like(DFR-like)protein in Arabidopsis.In BK2019,a 1-bp insertion was observed in the second exon of Bo9g058630 and directly produced a stop codon.To verify the candidate gene function,CRISPR/Cas9 gene editing technology was applied to knock out Bo9g058630.We generated three bona1 mutants,two of which were completely green with no anthocyanins,confirming that Bo9g058630 corresponds to BoNA1.Different insertion/deletion mutations in BoNA1 exons were found in all six of the other no-anthocyanin kale varieties examined,supporting that independent disruption of BoNA1 resulted in no-anthocyanin varieties of B.oleracea.This study improves the understanding of the regulation mechanism of anthocyanin accumulation in B.oleracea subspecies.
基金Supported by National Natural Science Foundation of China(Grant Nos.51975513,51890884)Zhejiang Provincial Natural Science Foundation of China(Grant No.LR20E050003)+1 种基金Major Research Plan of Ningbo Innovation 2025 of China(Grant No.2020Z022)Bellwethers Research and Development Plan of Zhejiang Province of China(Grant No.2023C01045).
文摘1 Introduction Digital Twin(DT)is built and maintained in the digital rather physical realm[1,2].Dynamic DT mirrors the exact state of the physical system by means of multidimensional models describing the behavior of physical entity,and sensors providing the real-time coupling to models[3].Te outbreak of COVID-19 pandemic results in speeding up the virtualization and digitization of the physical entity with the support from DT.Nevertheless,quarantine and division led by COVID-19 pandemic make human beings’eyes for the physical interaction become more eager.Te physical world and the digital world are becoming interwoven,which indicates a new opportunity towards phygital twin.As is so often the question:how can I get closer to my distant companion?How can I extend my service or emotional concern to facilitate interaction in spite of space obstruction?Tese questions deserve thinking as a lesson learned from outbreak of COVID-19 pandemic.
基金supported by grants from the National Key R&D Program of China(2023YFE0111400)the Key Technology R&D Program of Jiangsu Province(BE2023366)+4 种基金S&T Program of Hebei Province(22322912D)the Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences(CAAS-ASTIP-IVFCAAS)the China Agriculture Research System of MOF and MARA(CARS-23)Wulanchabu City's Chal enge and Recruitment Project(2022JB006)partly supported by the Russian Ministry of Science and Higher Education(No.075-15-2023-582)。
文摘Brassica oleracea is an important biennial herbaceous species in the Cruciferae family.With an estimated 3.77 million hectares planted worldwide,these cole crops,for instance,cabbage,broccoli,and cauliflower,constitute significant agricultural resources(Li et al.,2024).In recent years,the clustered regularly interspaced short palindromic repeats(CRISPR)/CRISPR-associated protein 9(Cas9)technology has been extensively applied in major crops,including rice,wheat,and potato.This technology can be utilized to regulate or disrupt gene expression to develop high-quality,disease-resistant.
基金supported by grants from the National Key R&D Program of China(2023YFD1201501)the Key Technology R&D Program of Jiangsu Province(BE2023366)+1 种基金the Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences(CAAS-ASTIP-IVFCAAS)the China Agriculture Research System of MOF and MARA(CARS-23).
文摘Global food production is a major challenge currently facing humanity,and the primary way to secure global food security is to increase crop yields and enhance nutritional value.Heterosis utilization by crossing of two different homozygous inbred lines has long been applied to increase crop yield.Doubled haploid(DH)technology greatly shortens the breeding process of homozygous lines by up to 3-5 years.In recent years,new haploid induction(HI)techniques based on genes such as DOMAIN OF UNKNOWN FUNCTION 679 membrane protein(DMP)and CENTROMERIC HISTONE3(CENH3)were exciting progresses in generating DHs in a more efficient and simple way(Jiang et al.,2022;Qu et al.,2024).
